多铁性
材料科学
自旋电子学
凝聚态物理
铁电性
铁磁性
拉曼光谱
磁化
拉曼散射
矫顽力
X射线吸收光谱法
压电响应力显微镜
居里温度
兴奋剂
光谱学
薄膜
纤锌矿晶体结构
光电子学
磁圆二色性
极化(电化学)
磁性半导体
半导体
铁磁材料性能
磁力显微镜
散射
吸收光谱法
作者
Juwon Lee,I.A. Kowalik,D. Arvanitis,Yongcheol Jo,Hak Dong Cho,Woochul Yang,Ji‐Hoon Kyhm
摘要
ABSTRACT Multiferroic materials that simultaneously exhibit ferroelectric and ferromagnetic order are highly attractive for multifunctional logic, memory, and spintronic devices. Here, we demonstrate robust room temperature multiferroicity in Bi doped ZnO (ZnBi 0.05 O 0.95 ) thin films grown by pulsed‐laser deposition. Structural analyses using XRD, HR‐TEM, and Raman spectroscopy unequivocally confirm single phase, c‐axis‐oriented wurtzite ZnO substitutional incorporation of Bi and no secondary phases. Ferroelectric switching behavior is verified through piezo‐response force microscopy (PFM), polarization‐electric field (P‐E), and current–voltage ( I – V ) measurements, yielding a remnant polarization of 0.36 µC cm −2 and coercive field of 125 kV cm −1 . Concurrently, magnetization studies reveal robust ferromagnetism persisting above 350 K. To elucidate the microscopic origin of the multiferroicity, X‐ray absorption spectroscopy (XAS) and resonant inelastic X‐ray scattering (RIXS) reveal a Bi‐induced downward shift of O 2p band edge together with pronounced modifications in the O 2p‐Zn hybridized states. These spectroscopic observations indicate Bi‐driven lattice distortion, hole introduction, and emergence of spin‐polarized Bi states. These cooperative structural and electronic reconstructions underpin the multiferroic response in ZnBi 0.05 O 0.95 , establishing this material as a promising silicon‐compatible multiferroic semiconductor for next‐generation multifunctional device technologies.
科研通智能强力驱动
Strongly Powered by AbleSci AI